Process Description
The SPM-2000 Batch Reactor Process Simulation can be configured to react any two gases. The reaction can be exothermic or endothermic. The default configuration reacts ethylene (reactant A) with benzene (reactant B), an exothermic reaction, to produce ethylbenzene (product C), an intermediate chemical used in the manufacture of styrene monomer. There are no side or competing reactions simulated.
Reactants A and B are fed to the Batch Reactor where they are completely mixed with a motorized agitator.
Reactant A feedstock is assumed to come from a typical refinery FCC. Consequently, there is a substantial concentration of inerts in the feed. Since the reaction is highly exothermic, the inerts serve to dilute the feed and aid in preventing a reactor run-away.
Reactant B feedstock is assumed to be of the highest available industrial grade and is therefore effectively 100% pure for the purposes of this simulation.
The reactor is sized to convert all of reactant A to product. The feed molar ratio of reactant B to reactant A is maintained at 3.25 to 1.
The product is purified downstream of the reactor through a series of distillation columns. The inerts are vented, recompressed, and used as a fuel gas elsewhere in the plant. Reactant B is recovered, purified, and recycled back to the reactor. The purification of the product stream is outside the scope of this simulation.
Instrumentation
The reactant A feed loop is outfitted with a composition analyzer (AI-101) that measures weight percent A, the balance being inerts. The supply temperature and pressure are indicated by TI-101 and PI-101 respectively. The feed block valve can be opened and closed with switch HV-101. Reactant A flow to the reactor is modulated by HIC-111. Total reactant A charge is indicated by FT-111.
The reactant B feed loop is outfitted with a composition analyzer (AI-102) that measures weight percent B, the balance being inerts. The supply temperature and pressure are indicated by TI-102 and PI-102 respectively. The feed block valve can be opened and closed with switch HV-102. Reactant B flow to the reactor is modulated by HIC-112. Total reactant B charge is indicated by FT-112.
The reactor contents are mixed by a motorized agitator which can be turned on and off with switch HS-123 and whose speed can be controlled with SIC-123.
Reactor temperature is indicated by TIC-123 which controls the reactor temperature by modulating the cooling and heating flows to the reactor jacket, indicated by FI-104 and FI-105 respectively. Total flow through the reactor jacket is indicated by FI-106. Cooling flow inlet temperature is indicated by TI-104, heating flow inlet temperature is indicated by TI-105, and reactor jacket outlet flow temperature is indicated by TI-106. The cooling flow block valve can be opened close with switch HV-104, the heating flow block valve can be opened and closed with switch HV-105, and the reactor jacket effluent block valve can be opened and closed with switch HV-106.
Reactor pressure is indicated by PI-123. HIC-123 modulates the reactor product flow. Total product discharged from the reactor is indicated by FT-123. The reactor effluent block valve can be opened and closed with switch HV-103. Product discharge pressure is indicated by PI-103.
Reactor compositions are indicated by AI-121 (WT% A), AI-122 (WT% B), and AI-123 (WT% C). Inerts compositions can be determined by difference.